Algebraic Nexus of Fibonacci Forms and Two-Simplex Topology in Multicellular Morphogenesis

Background: Fibonacci patterns and tubular forms both arose early in the phylogeny of multicellular organisms. Tubular forms offer the advantage of a regulated internal milieu, and Fibonacci forms may offer packing efficiencies. The underlying mechanisms behind the cellular genesis of Fibonacci and...

Full description

Saved in:
Bibliographic Details
Published inSymmetry (Basel) Vol. 16; no. 5; p. 516
Main Authors Butler Hoyos, William E., Andrade Loarca, Héctor, Kahle, Kristopher T., Williams, Ziv, Lamb, Elizabeth G., Alcántara, Julio, Kinane, Thomas Bernard, Turcio Cuevas, Luis J.
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.05.2024
Subjects
Adhesion
cell adhesion
Cell adhesion & migration
Cell cycle
Cellular structure
Chromosomes
Cytoskeleton
Eigenvalues
epigenomics
Extracellular matrix
Fibonacci
golden ratio
Macrostructure
Mathematical morphology
mitosis
Molecular properties
Multiplication
Organisms
Phylogeny
Proteins
Replication
simplex topology
Topology
Tubes
Online AccessGet full text

Cover

More Information
Summary:Background: Fibonacci patterns and tubular forms both arose early in the phylogeny of multicellular organisms. Tubular forms offer the advantage of a regulated internal milieu, and Fibonacci forms may offer packing efficiencies. The underlying mechanisms behind the cellular genesis of Fibonacci and tubular forms remain unknown. Methods: In a multicellular organism, cells adhere to form a macrostructure and to coordinate further replication. We propose and prove simple theorems connecting cell replication and adhesion to Fibonacci forms and simplicial topology. Results: We identify some cellular and molecular properties whereby the contact inhibition of replication by adhered cells may approximate Fibonacci growth patterns. We further identify how a component 2→3 cellular multiplication step may generate a multicellular structure with some properties of a two-simplex. Tracking the homotopy of a two-simplex to a circle and to a tube, we identify some molecular and cellular growth properties consistent with the morphogenesis of tubes. We further find that circular and tubular cellular aggregates may be combinatorially favored in multicellular adhesion over flat shapes. Conclusions: We propose a correspondence between the cellular and molecular mechanisms that generate Fibonacci cell counts and those that enable tubular forms. This implies molecular and cellular arrangements that are candidates for experimental testing and may provide guidance for the synthetic biology of hollow morphologies.
ISSN:2073-8994
2073-8994
DOI:10.3390/sym16050516